%-------------------------------------------------------------------------- % File : GEO001-0 : TPTP v7.2.0. Bugfixed v2.5.0 % Domain : Geometry (Tarskian) % Axioms : Tarski geometry axioms % Version : [MOW76] axioms. % English : % Refs : [Tar59] Tarski (1959), What is Elementary Geometry? % : [MOW76] McCharen et al. (1976), Problems and Experiments for a % : [Wos88] Wos (1988), Automated Reasoning - 33 Basic Research Pr % Source : [ANL] % Names : % Status : Satisfiable % Syntax : Number of clauses : 20 ( 6 non-Horn; 6 unit; 17 RR) % Number of atoms : 64 ( 8 equality) % Maximal clause size : 8 ( 3 average) % Number of predicates : 3 ( 0 propositional; 2-4 arity) % Number of functors : 8 ( 3 constant; 0-6 arity) % Number of variables : 79 ( 3 singleton) % Maximal term depth : 2 ( 1 average) % SPC : % Comments : These axioms are also used in [Wos88], p.206. % : outer_pasch : Skolem function arising from Outer Pasch Axiom (A7) % euclid1 : Skolem function arising from Euclid's Axiom (A8) % euclid2 : Skolem function arising from Euclid's Axiom (A8) % extend : Skolem function from Segment Construction (A10) % cont : Skolem function from Weakened Elementary Continuity (A13') % Bugfixes : v2.5.0 - Fixed clause continuity1. %-------------------------------------------------------------------------- cnf(identity_for_betweeness,axiom, ( ~ between(X,Y,X) | X = Y )). cnf(transitivity_for_betweeness,axiom, ( ~ between(X,Y,V) | ~ between(Y,Z,V) | between(X,Y,Z) )). cnf(connectivity_for_betweeness,axiom, ( ~ between(X,Y,Z) | ~ between(X,Y,V) | X = Y | between(X,Z,V) | between(X,V,Z) )). cnf(reflexivity_for_equidistance,axiom, ( equidistant(X,Y,Y,X) )). cnf(identity_for_equidistance,axiom, ( ~ equidistant(X,Y,Z,Z) | X = Y )). cnf(transitivity_for_equidistance,axiom, ( ~ equidistant(X,Y,Z,V) | ~ equidistant(X,Y,V2,W) | equidistant(Z,V,V2,W) )). cnf(outer_pasch1,axiom, ( ~ between(X,W,V) | ~ between(Y,V,Z) | between(X,outer_pasch(W,X,Y,Z,V),Y) )). cnf(outer_pasch2,axiom, ( ~ between(X,W,V) | ~ between(Y,V,Z) | between(Z,W,outer_pasch(W,X,Y,Z,V)) )). cnf(euclid1,axiom, ( ~ between(X,V,W) | ~ between(Y,V,Z) | X = V | between(X,Z,euclid1(W,X,Y,Z,V)) )). cnf(euclid2,axiom, ( ~ between(X,V,W) | ~ between(Y,V,Z) | X = V | between(X,Y,euclid2(W,X,Y,Z,V)) )). cnf(euclid3,axiom, ( ~ between(X,V,W) | ~ between(Y,V,Z) | X = V | between(euclid1(W,X,Y,Z,V),W,euclid2(W,X,Y,Z,V)) )). cnf(outer_five_segment,axiom, ( ~ equidistant(X,Y,X1,Y1) | ~ equidistant(Y,Z,Y1,Z1) | ~ equidistant(X,V,X1,V1) | ~ equidistant(Y,V,Y1,V1) | ~ between(X,Y,Z) | ~ between(X1,Y1,Z1) | X = Y | equidistant(Z,V,Z1,V1) )). cnf(segment_construction1,axiom, ( between(X,Y,extension(X,Y,W,V)) )). cnf(segment_construction2,axiom, ( equidistant(Y,extension(X,Y,W,V),W,V) )). cnf(lower_dimension1,axiom, ( ~ between(lower_dimension_point_1,lower_dimension_point_2,lower_dimension_point_3) )). cnf(lower_dimension2,axiom, ( ~ between(lower_dimension_point_2,lower_dimension_point_3,lower_dimension_point_1) )). cnf(lower_dimension3,axiom, ( ~ between(lower_dimension_point_3,lower_dimension_point_1,lower_dimension_point_2) )). cnf(upper_dimension,axiom, ( ~ equidistant(X,W,X,V) | ~ equidistant(Y,W,Y,V) | ~ equidistant(Z,W,Z,V) | between(X,Y,Z) | between(Y,Z,X) | between(Z,X,Y) | W = V )). cnf(continuity1,axiom, ( ~ equidistant(V,X,V,X1) | ~ equidistant(V,Z,V,Z1) | ~ between(V,X,Z) | ~ between(X,Y,Z) | equidistant(V,Y,V,continuous(X,Y,Z,X1,Z1,V)) )). cnf(continuity2,axiom, ( ~ equidistant(V,X,V,X1) | ~ equidistant(V,Z,V,Z1) | ~ between(V,X,Z) | ~ between(X,Y,Z) | between(X1,continuous(X,Y,Z,X1,Z1,V),Z1) )). %--------------------------------------------------------------------------